This application is based on and claims the benefit of priority from Japanese Patent Application No. 2022-047898 filed on Mar. 24, 2022, the contents of which are hereby incorporated by reference.
The present disclosure relates to a sheet discharge device for discharging sheets subjected to a folding process by which a sheet gets a fold or folds formed therein, and also relates to a sheet postprocessing device provided with the sheet discharge device.
There has been known heretofore a sheet postprocessing device provided with a sheet folding device that executes a folding process for forming a fold or folds on a sheet previously subjected to image formation by an image forming apparatus such as a copier and a printer.
A sheet discharge device according to one aspect of the present disclosure includes a sheet discharge part, a sheet discharge tray, a fullness detection sensor, a first sheet presser member, and a second sheet presser member. The sheet discharge part includes a discharge roller pair for discharging a folded sheet subjected to a folding process. The sheet discharge tray includes a tray upper surface on which the folded sheet discharged from the sheet discharge part is stacked, and a rear wall portion rising from an upstream-side end portion of the tray upper surface in the discharge direction. The fullness detection sensor is provided in the sheet discharge part to detect that a height of a stack surface of the folded sheets stacked on the tray upper surface has reached a specified height. The fullness detection sensor is located in a detection position in a widthwise direction perpendicular to the discharge direction, and has a detection region which has a specified width in a heightwise direction. The first sheet presser member is supported upward of the sheet discharge part, and extends toward the upstream side of the tray upper surface in the discharge direction, and the folded sheet discharged from the sheet discharge part is brought into contact with the first sheet presser member, and moreover the first sheet presser member presses the rear end side of the folded sheet stacked on the tray upper surface in the discharge direction. The second sheet presser member is supported upward of the sheet discharge part, extends toward a downstream side of the tray upper surface in the discharge direction, and presses a discharge-direction fore end side of the folded sheet stacked on the tray upper surface. The first sheet presser member is disposed outside the fullness detection sensor in the widthwise direction, extends from above the detection region to below the detection region. In a first pressing position with a fore end portion of the first sheet presser member facing upward of the stack surface, the first sheet presser member is brought into contact with an arbitrary position in a range from a central portion of the folded sheet of a minimum size stacked on the tray upper surface in the discharge direction to the rear wall portion, thereby pressing a swell of the folded sheet. When a stack number of the folded sheets has exceeded a specified number, the first sheet presser member is retracted upward from the first pressing position by the rise of the stack surface.
Hereinbelow, an embodiment of the present disclosure will be described in detail with reference to the accompanying drawings.
The image forming apparatus 200, as shown in
The sheet postprocessing device 1 is removably coupled to a side face of the image forming apparatus 200. The sheet postprocessing device 1 performs such postprocessing as a punch-hole forming process, a stapling process and a folding process on a sheet previously subjected to image formation (printing) by the image forming apparatus 200. It is noted that the sheet postprocessing device 1 is not limited to one which performs the postprocessing on a sheet automatically conveyed from the image forming apparatus 200, and may be one which allows a user to set a sheet on an unshown tray, the sheet then being conveyed up to a postprocessing-enabled position by the apparatus itself and subjected to the postprocessing.
The sheet inlet 2 is an opening provided in a side face of the sheet postprocessing device 1 facing the image forming apparatus 200. A sheet conveyed from the image forming apparatus 200 toward the sheet postprocessing device 1 is conveyed through the sheet inlet 2 to get inside the sheet postprocessing device 1.
The first sheet conveyance path 3 extends from the sheet inlet 2 to the first sheet discharge part 4 in such a generally horizontal direction (leftward direction in
The first sheet discharge part 4 is provided on a side face of the sheet postprocessing device 1 opposite to its side face facing the image forming apparatus 200. The first sheet discharge part 4 is placed at a downstream end of the first sheet conveyance path 3 in the sheet conveyance direction. The first sheet discharge part 4 includes a first discharge port 41, a first discharge roller pair 42, and a first discharge tray 43.
The first discharge port 41 is located at a downstream end of the first sheet conveyance path 3 in the sheet conveyance direction. The first discharge roller pair 42 is placed at the first discharge port 41. The first discharge tray 43 is located on a downstream side of the first discharge port 41 in the sheet conveyance direction. A sheet conveyed along the first sheet conveyance path 3 and having reached the first discharge port 41 is passed through the first discharge port 41 by the first discharge roller pair 42 so as to be discharged onto the first discharge tray 43. The first discharge tray 43 is one of terminal discharge places for sheets subjected to the postprocessing by the sheet postprocessing device 1. Also discharged to the first discharge tray 43 are sheets subjected to no postprocessing, sheets of small sizes, and the like.
The second sheet conveyance path 5, branching from a first branch portion (branch portion) 31 on the first sheet conveyance path 3, extends up to the second sheet discharge part 6 in such a horizontal direction as to become farther (leftward direction in
The first branch portion 31 includes a first switching guide 311. The first switching guide 311 turns between a first position (broken line P1 in
The second sheet discharge part 6 is provided upward of the first sheet discharge part 4 and on the side face of the sheet postprocessing device 1 opposite to its side face facing the image forming apparatus 200. The second sheet discharge part 6 is placed at a downstream end of the second sheet conveyance path 5 in the sheet conveyance direction. The second sheet discharge part 6 includes a second discharge port 61, a second discharge roller pair 62, and a second discharge tray 63.
The second discharge port 61 is located at a downstream end of the second sheet conveyance path 5 in the sheet conveyance direction. The second discharge roller pair 62 is placed at the second discharge port 61. The second discharge tray 63 is located on a downstream side of the second discharge port 61 in the sheet conveyance direction. A sheet conveyed along the second sheet conveyance path 5 and having reached the second discharge port 61 is passed through the second discharge port 61 by the second discharge roller pair 62 so as to be discharged onto the second discharge tray 63. The second discharge tray 63 is one of terminal discharge places for sheets subjected to postprocessing by the sheet postprocessing device 1.
The third sheet conveyance path 7, branching from a second branch portion 32 on the first sheet conveyance path 3, extends downward to reach the third sheet discharge part 8. It is noted that a direction from the second branch portion 32 toward the third sheet discharge part 8 is referred to as a sheet conveyance direction of the third sheet conveyance path 7. The second branch portion 32 is located on a downstream side of the first branch portion 31 as viewed in the sheet conveyance direction of the first sheet conveyance path 3 and moreover located at a sheet-conveyance upstream end of the third sheet conveyance path 7. The third sheet conveyance path 7, having a plurality of conveyance roller pairs 7r, leads a sheet, which is under conveyance on the first sheet conveyance path 3, such that the sheet branches at the second branch portion 32 so as to be conveyed toward the third sheet discharge part 8.
The second branch portion 32 includes a second switching guide 321. The second switching guide 321 turns between a first position (see
The third sheet discharge part 8 is provided downward of the first sheet discharge part 4 (near a lower end portion of the sheet postprocessing device 1) and on the side face of the sheet postprocessing device 1 opposite to its side face facing the image forming apparatus 200. The third sheet discharge part 8 includes a third discharge port 81, a third discharge roller pair 82, and a third discharge tray 83.
The third discharge port 81 is located at a downstream end of the third sheet conveyance path 7 in the sheet conveyance direction. The third discharge roller pair 82 is placed at the third discharge port 81. The third discharge tray 83 is located on a downstream side of the third discharge port 81 in the sheet conveyance direction. A sheet conveyed on the third sheet conveyance path 7 and having reached the third discharge port 81 is discharged onto the third discharge tray 83 through the third discharge port 81 by the third discharge roller pair 82. The third discharge tray 83 is one of terminal discharge places for sheets subjected to postprocessing by the sheet postprocessing device 1.
The postprocessing part 9 performs specified postprocessing on a sheet subjected to image formation by the image forming apparatus 200 and conveyed into the sheet postprocessing device 1. The postprocessing part 9 includes the punching portion 91, a stapling portion 92, a sheet folding unit 100, and a bookbinding portion 94.
The punching portion 91 is placed in downstream-side close vicinity of the sheet inlet 2 in the first sheet conveyance path 3. The punching portion 91 performs a punching process on a sheet conveyed on the first sheet conveyance path 3, making a punch hole formed thereon.
The stapling portion 92 is placed in upstream-side close vicinity of the first sheet discharge part 4 as viewed in the sheet conveyance direction of the first sheet conveyance path 3. The stapling portion 92 performs a stapling process on a sheet bundle formed by stacking a plurality of sheets, by which the sheet bundle is stapled.
The sheet folding unit 100 is placed downstream of the punching portion 91 and upstream of the stapling portion 92, as viewed in the sheet conveyance direction of the first sheet conveyance path 3. In other words, the sheet folding unit 100 is located on an upstream side of the first branch portion 31, as viewed in the sheet conveyance direction of the first sheet conveyance path 3. The sheet folding unit 100 performs the folding process on one sheet to form a fold or folds thereon.
The sheet folding unit 100 is enabled to perform, for one sheet, such folding processes as two-folding, Z-folding, outward three-folding, and inward three-folding. A detailed configuration of the sheet folding unit 100 will be described later.
The Z-folding, as shown in
The outward three-folding, as shown in
The inward three-folding, as shown in
The bookbinding portion 94 is placed in upstream-side close vicinity of the third sheet discharge part 8 as viewed in the sheet conveyance direction of the third sheet conveyance path 7. The bookbinding portion 94 includes a middle-folding portion 941, a middle-stitching portion 942. The bookbinding portion 94 performs, on a sheet bundle formed by stacking a plurality of sheets, a middle-folding process and a middle-stitching process for folding and stitching a generally central portion of the sheet bundle in the sheet conveyance direction to make up a booklet.
The postprocessing control part 10 includes a CPU, a storage part, and other electronic circuits and electronic components (none are shown). The postprocessing control part 10 is communicatably connected to an apparatus control part of the image forming apparatus 200 (see
Subsequently, a configuration of the sheet folding unit 100 is described with reference to
Also, conveyance roller pairs 3r are placed, along the first sheet conveyance path 3, at two sites in the sheet folding unit 100. Hereinbelow, out of the conveyance roller pairs 3r placed at two sites in the sheet folding unit 100, an upstream-side conveyance roller pair 3r composed of a second roller 112 and a conveyance roller 114 is assumed as a first assist roller pair 3r1, and a downstream-side conveyance roller pair 3r is assumed as a second assist roller pair 3r2.
The first folding portion 101 is placed on the first sheet conveyance path 3. In more detail, the first folding portion 101 is located downstream of the punching portion 91 (see
The first folding conveyance path 102 branches from the first folding portion 101 on the first sheet conveyance path 3 and extends downward. In this embodiment, the first folding conveyance path 102 extends generally vertically downward from the first folding portion 101. A lower end portion of the first folding conveyance path 102 connects to the third sheet conveyance path 7.
The first folding roller pair 103 is placed on the first folding conveyance path 102 in the first folding portion 101. The first folding roller pair 103 is composed of a first roller 111 placed on one side of the first folding conveyance path 102, and the second roller 112 placed on the other side of the first folding conveyance path 102. In the first folding roller pair 103, one of the first roller 111 and the second roller 112 is biased toward the other into contact therebetween, causing a first folding nip portion N1 to be formed. A sheet that has entered the first folding conveyance path 102, passing through the first folding nip portion N1, is conveyed downward of the first folding roller pair 103.
In addition, the second roller 112 in combination with the conveyance roller 114 makes up the first assist roller pair 3r1.
The first folding guide 104 is placed opposite to the first folding nip portion N1 in the first folding portion 101. In more detail, the first folding guide 104 is placed upstream (upper side in
The first folding guide 104 is connected to a guide drive mechanism (not shown) and enabled to reciprocate in such directions as to become closer to and farther from the first folding nip portion N1. The first folding guide 104 leads a sheet, which is under conveyance on the first sheet conveyance path 3, to the first folding nip portion N1.
The second folding portion 105 is placed on the first folding conveyance path 102. In more detail, the second folding portion 105 is located downstream of the first folding roller pair 103 as viewed in the sheet conveyance direction of the first folding conveyance path 102 and moreover downward of the first folding nip portion N1.
The second folding conveyance path 106 branches and extends from the second folding portion 105 on the first folding conveyance path 102. The second folding conveyance path 106 extends from the second folding portion 105 toward the side face (left side in
The first sheet conveyance path 3 includes a merging portion 33 located downstream of the first branch portion 31 in the sheet conveyance direction. The second folding conveyance path 106 merges with the first sheet conveyance path 3 at the merging portion 33. In other words, the merging portion 33 is located downstream of the first branch portion 31 as viewed in the sheet conveyance direction of the first sheet conveyance path 3, and a sheet subjected a folding process by the sheet folding unit 100 merges together.
In this embodiment, the merging portion 33 is located in close vicinity to the first switching guide 311. The first switching guide 311 is switchable among a first position P1, a second position P2, and a third position P3 (see
The second folding roller pair 107 is placed on the second folding conveyance path 106 in the second folding portion 105. The second folding roller pair 107 is composed of the first roller 111 placed on one side of the second folding conveyance path 106 and a third roller 113 placed on the other side, with the second folding conveyance path 106 interposed therebetween. In the second folding roller pair 107, one of the first roller 111 and the third roller 113 is biased against the other into contact with each other, by which a second folding nip portion N2 is formed. A sheet that has entered the second folding conveyance path 106, passing through the second folding nip portion N2, is conveyed toward the merging portion 33 (leftward of the second folding roller pair 107 in
The second folding guide 108 is placed opposite to the second folding nip portion N2 in the second folding portion 105. In more detail, the second folding guide 108 is placed upstream (right side in
The second folding guide 108 is connected to a drive mechanism (not shown) and enabled to reciprocate in such directions as to become closer to and farther from the second folding nip portion N2. The second folding guide 108 leads a sheet, which is under conveyance on the first folding conveyance path 102, to the second folding nip portion N2.
Subsequently, operation of the sheet folding unit 100 is described with reference to
As shown in
In addition, in the first folding portion 101, the first folding guide 104 is placed at such a position (retract position) as to have retracted in a direction of becoming farther from the first folding nip portion N1 than the first sheet conveyance path 3, i.e., retracted upward of the first sheet conveyance path 3 as viewed in
When a site of the sheet S corresponding to the first fold F1 (see
With the first assist roller pair 3r1 stopped, the second assist roller pair 3r2 and the conveyance roller pairs 5r of the second sheet conveyance path 5 are rotated reverse, so that a portion of the sheet S located on the downstream side of the first assist roller pair 3r1 is moved to the upstream side (right side in
The second assist roller pair 3r2 is further rotated reverse, and the first folding guide 104 is moved to such a position (folding position) as to come into contact with the first folding nip portion N1 via the sheet S. Movement of the first folding guide 104 from the retract position to the folding position causes the flexed portion of the sheet S to be guided to the first folding nip portion N1. Thus, making the first folding guide 104 moved to the folding position after the formation of a flexure in the sheet S makes it possible to suppress occurrence of creases or breaks of the sheet S because no excessive load due to the first folding guide 104 acts on the sheet S. The first fold F1 is formed in the sheet S that has passed through the first folding nip portion N1.
In addition, a timing for forming the first fold F1 in the sheet S is determined based on a detection timing of a downstream end of the sheet S, as viewed in the sheet conveyance direction of the first sheet conveyance path 3, by a sheet detection sensor (not shown), as well as based on an overall length of the sheet S in the sheet conveyance direction and a conveyance speed of the sheet S. The case is the same also with a timing for forming a later-described second fold F2.
In the second folding portion 105, the second folding guide 108 retracts in such a direction (right side of the first folding conveyance path 102 in
The sheet S that has passed through the first folding nip portion N1 is conveyed in the first folding conveyance path 102 in such a direction (downward direction) as to become farther from the first folding roller pair 103 while the sheet S is headed by the first fold F1 site and its two regions extending along the sheet conveyance direction are overlapped with each other. An upstream portion of the sheet S in the sheet conveyance direction that has passed through the first folding conveyance path 102 temporarily enters the third sheet conveyance path 7.
When a site of the sheet S corresponding to the second fold F2 (see
After the sheet S has been stopped from conveyance, the individual conveyance roller pairs 7r of the third sheet conveyance path 7 are rotated reverse, so that a downstream side (a side lower than the second folding portion 105 in
Subsequently, the second folding guide 108 is moved in such a direction as to become closer to the second folding nip portion N2, coming into contact with the sheet S. The contact of the second folding guide 108 causes the flexure portion of the sheet S to be guided to the second folding nip portion N2 of the second folding roller pair 107. Then, a second fold F2 is formed in the sheet S that has passed through the second folding nip portion N2 (see
As shown in
In a case where a sheet S is subjected to a folding process by the sheet folding unit 100, the postprocessing control part 10 leads a downstream portion of the sheet S in the sheet conveyance direction, which has been conveyed through the sheet inlet 2 into the first sheet conveyance path 3, from the first branch portion 31 to the second sheet conveyance path 5, then reverses the conveyance direction of the sheet S and leads the sheet S to the sheet folding unit 100, where the sheet S is subjected to the folding process. Further, the postprocessing control part 10 merges the sheet S, which has been subjected to the folding process, with the second sheet conveyance path 5 at the merging portion 33.
The above description has been made on the inward three-folding process with the sheet S. Also for the Z-folding process in which the sheet S is subjected to Z-folding shown in
The second discharge tray 63 includes a tray upper surface 63a on which sheets subjected to a folding process by the sheet folding unit 100 and discharged through the second discharge port 61 (hereinafter, those sheets will be referred to as folded sheets) are to be stacked, and a rear wall portion 63b rising from a downstream-side end portion of the tray upper surface 63a in a discharge direction.
The first sheet presser member 65 has one end portion (base end portion) fixed upward of the second discharge roller pair 62, and the other end portion (fore end portion 65a) extending downward of the second discharge roller pair 62. The first sheet presser member 65 is brought into contact with a folded sheet discharged through the second discharge port 61 so as to press a portion of sheets stacked on the tray upper surface 63a of the second discharge tray 63, the pressed portion generally ranging from upstream-side end portion to central portion of the stacked sheets in the discharge direction.
The first sheet presser member 65 is an elastically deformable sheet-like member. The first sheet presser member 65 is elastically deformed in response to a stack number of folded sheets stacked on the tray upper surface 63a, causing a pressing portion of folded sheets to be varied. As a material of the first sheet presser member 65, polyethylene terephthalate (PET) films having a thickness of 0.2 to 0.3 mm may be mentioned as an example.
The first sheet presser member 65 may be formed from a platy member that is swingable by its self weight along the sheet discharge direction (from-right leftward direction in
The second sheet presser member 67 presses a portion of a folded sheet discharged and stacked on the tray upper surface 63a of the second discharge tray 63, the pressed portion generally ranging from downstream-side fold portion to central portion of the stacked sheet in the discharge direction. The second sheet presser member 67 is swingably supported by a rotational fulcrum 67a provided downstream of the first sheet presser member 65 in the discharge direction. The second sheet presser member 67 swings toward the downstream side (in a clockwise direction in
The first sheet presser member 65 and the second sheet presser member 67 are retained by a retaining member 68. The retaining member 68 is attachable to and detachable from the second sheet discharge part 6. The first sheet presser member 65 and the second sheet presser member 67 are attachable to and detachable from the second sheet discharge part 6 integrally together with the retaining member 68.
The second sheet discharge part 6 includes a fullness detection sensor 69. The fullness detection sensor 69 is placed at a site inside (upstream side in the discharge direction) a rear wall surface 63b of the second discharge tray 63 and nearly immediately under the second discharge roller pair 62 to detect a full state of folded sheets stacked on the tray upper surface 63a. The fullness detection sensor 69, while in a detection position in a widthwise direction perpendicular to the discharge direction, has a detection region R (see
The fullness detection sensor 69 is a reflection-type PI (photointerrupter) sensor equipped with a detection part including a light-emitting portion and a light-receiving portion. When the stack quantity of folded sheets stacked on the tray upper surface 63a has come to a certain number of sheets (e.g., 30 sheets) or more, a stacking surface (top surface) of folded sheets reaches the detection region R of the fullness detection sensor 69. In this state, the detection part of the fullness detection sensor 69 is enabled to detect reflected light from folded sheets, so that the fullness detection sensor 69 detects a full state of folded sheets stacked on the tray upper surface 63a.
A folded sheet S1 is obtained by inwardly three-folding (see
A folded sheet S3 is obtained by Z-folding (see
The first sheet presser member 65 presses a rear end portion of a folded sheet that has reached the detection region R of the fullness detection sensor 69, thereby securing the stack quantity of folded sheets stacked on the second discharge tray 63. The first sheet presser member 65 presses an arbitrary position within a range from central portion in the discharge direction to the rear wall portion 63b (a range of 50 mm distance from the rear wall portion 63b) in the folded sheet S1 of the minimum size stacked on the tray upper surface 63a of the second discharge tray 63. Also, in a first pressing position in which the fore end portion 65a protrudes downward of a lower limit of the detection region R (inside of a triangle in
As a consequence, the first sheet presser member 65 is enabled to securely press a vicinity of the rear end portion of three-folded sheets S1 and S2, which would get swollen largely on their rear end side. Accordingly, the stack quantity of folded sheets S1 and S2 stacked on the second discharge tray 63 can be secured by avoiding misdetections of the fullness detection sensor 69 due to rear-end-side swells of the folded sheets S1 and S2. Also, occurrence of slip-in of folded sheets due to blockage of the second discharge port 61 by the rear end portion of the folded sheets S1 to S5 is suppressed by the pressing of a vicinity of the rear end portion of folded sheets S1 to S5. As a result, stackability of the folded sheets S1 to S5 can be improved.
In addition, there is a fear that collision loads against the first sheet presser member 65 may cause rounding or jamming of folded sheets S1 to S5 discharged from the second discharge port 61. Accordingly, a collision angle θ1 between the first sheet presser member 65 and a fore end of folded sheets S1 to S5 discharged from the second discharge port 61 is preferably set to 85° or less under a condition that no external force is applied to the first sheet presser member 65 (in the initial position).
By pressing a vicinity of folds in fore end portions of folded sheets S1 to S5 stacked on the tray upper surface 63a, the second sheet presser member 67 secures the stack quantity of folded sheets S1 to S5 on the tray upper surface 63a. A fore end portion 67b of the second sheet presser member 67 presses an arbitrary position within a range from central portion in the discharge direction of the folded sheet S5 of the maximum size stacked on the tray upper surface 63a to fore-end-side fold portion in the discharge direction of the folded sheet S1 of the minimum size (a range of 100 to 140 mm distance from the rear wall portion 63b). Also, in a second pressing position in which the fore end portion 67b protrudes downward of the lower limit of the detection region R of the fullness detection sensor 69, the second sheet presser member 67 presses a swell of folded sheets S1 to S5. When the stack number of folded sheets S1 to S5 has exceeded a specified number of sheets, the second sheet presser member 67 is rocked upward by an ascent of the stack surface (upper surface) of the folded sheets S1 to S5, so that the second sheet presser member 67 retracts from the second pressing position, permitting the stack surface of the folded sheets S1 to S5 to ascend.
As a consequence, the second sheet presser member 67 is enabled to securely press a vicinity of a fold of Z-folded sheets S3 and S4, which would get swollen largely on their fore end side. Accordingly, the stack quantity of folded sheets S3 to S5 stacked on the second discharge tray 63 can be secured by avoiding misdetections of the fullness detection sensor 69 due to fore-end-side swells of the folded sheets S3 and S4. Also, occurrence of push-out of folded sheets due to subsequent folded sheets S1 to S5 is suppressed by the pressing of central portion to fore end portion of the folded sheets S1 to S5 in the discharge direction already stacked on the second discharge tray 63. As a result, alignment of the folded sheets S1 to S5 in the discharge direction and the widthwise direction can be improved.
In this connection, in a case where the second sheet presser member 67 is so placed that the fore end portion 67b of the second sheet presser member 67 presses a vicinity of a fold of folded sheets S3 and S4, it becomes impossible for the fore end portion 67b of the second sheet presser member 67 to press a fold portion on the fore end side of the folded sheet S1 of the minimum size. Therefore, a sloped surface 67c which is sloped from the fore end portion 67b in such a direction as to become closer to the tray upper surface 63a is formed at a lower surface of the second sheet presser member 67. In more detail, the sloped surface 67c is sloped in such a direction as to become farther and farther from an upper surface of the second sheet presser member 67 as a distance from the fore end portion 67b increases more and more toward the upstream side (right side in
In addition, there is a fear that collision loads against the second sheet presser member 67 may cause rounding or jamming of folded sheets discharged from the second discharge port 61. Accordingly, a collision angle θ2 between the second sheet presser member 67 and a fore end of folded sheets S1 to S5 discharged from the second discharge port 61 is preferably set to 40° or less under a condition that the fore end portion 67b of the second sheet presser member 67 is positioned in contact with the second discharge tray 63 (initial position, broken-line position in
Although an embodiment of the present disclosure has been described hereinabove, the scope of the disclosure is not limited to this, and various modifications and changes may be made unless departing from the gist of the invention. For example, the above-described embodiment has been described on a case where the sheet folding unit 100 includes the first folding roller pair 103, and the second folding roller pair 107, which is composed of three rollers of the first roller 111 to the third roller 113. However, the disclosure is not limited to this, and the sheet folding unit 100 may include only the first folding roller pair 103 composed of the first roller 111 and the second roller 112.
Further, in the above embodiment, sheets subjected to a folding process by the sheet folding unit 100 are discharged to the second sheet discharge part 6. Alternatively, sheets subjected to a folding process may be discharged instead to the first sheet discharge part 4. In this case, the first sheet presser member 65 and the second sheet presser member 67 may appropriately be placed in the first sheet discharge part 4.
Furthermore, in the above embodiment, the sheet discharge device of the disclosure has been exemplified by the second sheet discharge part 6 of the sheet postprocessing device 1 including the sheet folding unit 100 by which sheets are subjected to the folding process. However, the disclosure is not limited to this. For example, the disclosure may be applied similarly to a sheet discharge part of a sheet postprocessing device 1 which includes no sheet folding unit 100 and into which folded sheets subjected to the folding process by a separately provided sheet folding device are to be conveyed.
The present disclosure is applicable to sheet discharge devices for discharging sheets subjected to a folding process of forming a fold in the sheets, as well as to postprocessing devices each including such a sheet discharge device.
Number | Date | Country | Kind |
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2022-047898 | Mar 2022 | JP | national |
Number | Name | Date | Kind |
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7866647 | Terao | Jan 2011 | B2 |
Number | Date | Country |
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2002-255431 | Sep 2002 | JP |
2009-062111 | Mar 2009 | JP |
Number | Date | Country | |
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20230303356 A1 | Sep 2023 | US |